Balmer given an equation for wavelength of visible radiation of H-spectrum as `lambda=(kn^(2))/(n^(2)-4)`.The value of k in terms of Rydbrum constant R is

Balmer gave an equation for wavelength of visible radiation of H-spectrum as lambda=(kn^(2))/(n^(2)-4) . The value of k in terms of Rydberg's constant R is m//R , where m is :

Balmer gives an equation for wavelength of visible radition of H^(-) spectrum as lambda=(kn^(2))/(n^(2)-4) .The value of k in terms of Rydberg's constant R is

Balmer gave an equation for wavelegth of visible region of H-spectrum as lambda=(Kn^(2))/(n^(2)-4). Where n= pricipal quantum number of energy level, K=constant in terms of R (Rydberg constant). The value of K in term of R is :

The wave number of the first emission line in the Balmer series of H - Spectrum is (n)/(36)R . The value of 'n' is. (R = Rydberg constant):

If the wavelength of H_alpha line of Balmer seriesin hydrogen spectrum is 6.5xx10^(-7) m then find the value of Rydberg constant.

The wavelength of emitted radiation in terms of R (the Rydberg constant) is lambda = 36//5 R . The electron jumps from

If He^(+) ions are known to have the wavelength difference of the first lines of Balmer series and first line of Lyman series equal to Delta lambda=132nm then the value of Rydberg constant (R) is